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Mechanical Retention and Waterproof Properties of Bacterial Cellulose-Reinforced Thermoplastic Starch Biocomposites Modified with Sodium Hexametaphosphate

The waterproof and strength retention properties of bacterial cellulose (BC)-reinforced thermoplastic starch (TPS) resins were successfully improved by reacting with sodium hexametaphosphate (SHMP). After modification with SHMP, the tensile strength ( sigma f) and impact strength (Is) values of init...

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Published in:	Materials 2015, Vol.8 (6), p.3168-3194
Main Authors:	Wang, Da-wei, Xu, Ying-juan, Li, Xin, Huang, Chao-ming, Huang, Kuo-shien, Wang, Chuen-kai, Yeh, Jen-taut
Format:	Article
Language:	English
Subjects:	Acids Bacteria Cellulose Conditioning Diffraction patterns Electronic mail systems Engineering Impact strength Materials science Moisture content Organic chemicals Polymer blends Polymers Resins Retention Sodium Starches
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cited_by	cdi_FETCH-LOGICAL-c413t-ef37773e113a296a20c619f06df199fceb78ec175a5a52d5ebb57b9e04e6ea173
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creator	Wang, Da-wei Xu, Ying-juan Li, Xin Huang, Chao-ming Huang, Kuo-shien Wang, Chuen-kai Yeh, Jen-taut
description	The waterproof and strength retention properties of bacterial cellulose (BC)-reinforced thermoplastic starch (TPS) resins were successfully improved by reacting with sodium hexametaphosphate (SHMP). After modification with SHMP, the tensile strength ( sigma f) and impact strength (Is) values of initial and conditioned BC-reinforced TPS, modified with varying amounts of SHMP(TPS100BC0.02SHMPx), and their blends with poly(lactic acid)((TPS100BC0.02SHMPx)75PLA25) specimens improved significantly and reached a maximal value as SHMP content approached 10 parts per hundred parts of TPS resin (phr), while their moisture content and elongation at break ( epsilon f) was reduced to a minimal value as SHMP contents approached 10 phr. The sigma f, Is and epsilon f retention values of a (TPS100BC0.02SHMP10)75PLA25 specimen conditioned for 56 days are 52%, 50% and 3 times its initial sigma f, Is and epsilon f values, respectively, which are 32.5 times, 8.9 times and 40% of those of a corresponding conditioned TPS100BC0.02 specimen, respectively. As evidenced by FTIR analyses of TPS100BC0.02SHMPx specimens, hydroxyl groups of TPS100BC0.02 resins were successfully reacted with the phosphate groups of SHMP molecules. New melting endotherms and diffraction peaks of VH-type crystals were found on DSC thermograms and WAXD patterns of TPS or TPS100BC0.02 specimens conditioned for 7 days, while no new melting endotherm or diffraction peak was found for TPS100BC0.02SHMPx and/or (TPS100BC0.02SHMPx)75PLA25 specimens conditioned for less than 14 and 28 days, respectively.
doi_str_mv	10.3390/ma8063168
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After modification with SHMP, the tensile strength ( sigma f) and impact strength (Is) values of initial and conditioned BC-reinforced TPS, modified with varying amounts of SHMP(TPS100BC0.02SHMPx), and their blends with poly(lactic acid)((TPS100BC0.02SHMPx)75PLA25) specimens improved significantly and reached a maximal value as SHMP content approached 10 parts per hundred parts of TPS resin (phr), while their moisture content and elongation at break ( epsilon f) was reduced to a minimal value as SHMP contents approached 10 phr. The sigma f, Is and epsilon f retention values of a (TPS100BC0.02SHMP10)75PLA25 specimen conditioned for 56 days are 52%, 50% and 3 times its initial sigma f, Is and epsilon f values, respectively, which are 32.5 times, 8.9 times and 40% of those of a corresponding conditioned TPS100BC0.02 specimen, respectively. As evidenced by FTIR analyses of TPS100BC0.02SHMPx specimens, hydroxyl groups of TPS100BC0.02 resins were successfully reacted with the phosphate groups of SHMP molecules. 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After modification with SHMP, the tensile strength ( sigma f) and impact strength (Is) values of initial and conditioned BC-reinforced TPS, modified with varying amounts of SHMP(TPS100BC0.02SHMPx), and their blends with poly(lactic acid)((TPS100BC0.02SHMPx)75PLA25) specimens improved significantly and reached a maximal value as SHMP content approached 10 parts per hundred parts of TPS resin (phr), while their moisture content and elongation at break ( epsilon f) was reduced to a minimal value as SHMP contents approached 10 phr. The sigma f, Is and epsilon f retention values of a (TPS100BC0.02SHMP10)75PLA25 specimen conditioned for 56 days are 52%, 50% and 3 times its initial sigma f, Is and epsilon f values, respectively, which are 32.5 times, 8.9 times and 40% of those of a corresponding conditioned TPS100BC0.02 specimen, respectively. As evidenced by FTIR analyses of TPS100BC0.02SHMPx specimens, hydroxyl groups of TPS100BC0.02 resins were successfully reacted with the phosphate groups of SHMP molecules. New melting endotherms and diffraction peaks of VH-type crystals were found on DSC thermograms and WAXD patterns of TPS or TPS100BC0.02 specimens conditioned for 7 days, while no new melting endotherm or diffraction peak was found for TPS100BC0.02SHMPx and/or (TPS100BC0.02SHMPx)75PLA25 specimens conditioned for less than 14 and 28 days, respectively.</abstract><cop>Basel</cop><pub>MDPI AG</pub><doi>10.3390/ma8063168</doi><tpages>27</tpages><oa>free_for_read</oa></addata></record>
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source	Publicly Available Content Database; PubMed Central; Free Full-Text Journals in Chemistry
subjects	Acids Bacteria Cellulose Conditioning Diffraction patterns Electronic mail systems Engineering Impact strength Materials science Moisture content Organic chemicals Polymer blends Polymers Resins Retention Sodium Starches
title	Mechanical Retention and Waterproof Properties of Bacterial Cellulose-Reinforced Thermoplastic Starch Biocomposites Modified with Sodium Hexametaphosphate
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